Capital structure determinants and adjustment speed: An empirical analysis of Dutch SMEs

Similar documents
Cash holdings determinants in the Portuguese economy 1

UNOBSERVABLE EFFECTS AND SPEED OF ADJUSTMENT TO TARGET CAPITAL STRUCTURE

The Role of Credit Ratings in the. Dynamic Tradeoff Model. Viktoriya Staneva*

On the impact of financial distress on capital structure: The role of leverage dynamics

How Do Firms Finance Large Cash Flow Requirements? Zhangkai Huang Department of Finance Guanghua School of Management Peking University

The Debt-Equity Choice of Japanese Firms

On the Investment Sensitivity of Debt under Uncertainty

The Debt-Equity Choice of Japanese Firms

THE SPEED OF ADJUSTMENT TO CAPITAL STRUCTURE TARGET BEFORE AND AFTER FINANCIAL CRISIS: EVIDENCE FROM INDONESIAN STATE OWNED ENTERPRISES

What is the effect of the financial crisis on the determinants of the capital structure choice of SMEs?

An Empirical Investigation of the Trade-Off Theory: Evidence from Jordan

CAPITAL STRUCTURE AND THE 2003 TAX CUTS Richard H. Fosberg

Capital Structure and the 2001 Recession

Leverage dynamics, the endogeneity of corporate tax status and financial distress costs, and capital structure

Bank Concentration and Financing of Croatian Companies

Local Government Spending and Economic Growth in Guangdong: The Key Role of Financial Development. Chi-Chuan LEE

CHAPTER 2 LITERATURE REVIEW. Modigliani and Miller (1958) in their original work prove that under a restrictive set

Ownership Structure and Capital Structure Decision

TRADE-OFF THEORY VS. PECKING ORDER THEORY EMPIRICAL EVIDENCE FROM THE BALTIC COUNTRIES 3

Does Manufacturing Matter for Economic Growth in the Era of Globalization? Online Supplement

Capital Structure Decisions under Institutional Factors and Asymmetric Adjustments

The Existence of Inter-Industry Convergence in Financial Ratios: Evidence From Turkey

The Effect of Financial Constraints, Investment Policy and Product Market Competition on the Value of Cash Holdings

Internal Finance and Growth: Comparison Between Firms in Indonesia and Bangladesh

CORPORATE TAX INCENTIVES AND CAPITAL STRUCTURE: EVIDENCE FROM UK TAX RETURN DATA

Uncertainty Determinants of Firm Investment

CORPORATE CASH HOLDING AND FIRM VALUE

Capital structure and profitability of firms in the corporate sector of Pakistan

Ownership Concentration and Capital Structure Adjustments

GMM for Discrete Choice Models: A Capital Accumulation Application

International Journal of Multidisciplinary Consortium

Leverage and the Jordanian Firms Value: Empirical Evidence

Long-run Consumption Risks in Assets Returns: Evidence from Economic Divisions

Advances in Environmental Biology

Deviations from Optimal Corporate Cash Holdings and the Valuation from a Shareholder s Perspective

Capital Structure Determinants of Small and Medium Enterprises in Croatia

Impact of credit risk (NPLs) and capital on liquidity risk of Malaysian banks

Volume 29, Issue 2. A note on finance, inflation, and economic growth

The Impact of Firm and Industry Characteristics on Small Firms' Capital Structure Degryse, Hans; de Goeij, Peter; Kappert, P.

Depression Babies: Do Macroeconomic Experiences Affect Risk-Taking?

The Determinants of Capital Structure: Analysis of Non Financial Firms Listed in Karachi Stock Exchange in Pakistan

Transaction Costs and Capital-Structure Decisions: Evidence from International Comparisons

The long- and short-term determinants of the capital structure of Polish companies 3.

Equity Financing and Innovation:

Short-termism in business: causes, mechanisms and consequences APPENDIX. Details of the econometric analysis

Current Account Balances and Output Volatility

Deregulation and Firm Investment

Testing the static trade-off theory and the pecking order theory of capital structure: Evidence from Dutch listed firms

Impact of Capital Market Expansion on Company s Capital Structure

Impact of Foreign Direct Investment on Economic Growth: Do Host Country Social and Economic Conditions Matter?

DIVIDEND POLICY AND THE LIFE CYCLE HYPOTHESIS: EVIDENCE FROM TAIWAN

The Role of APIs in the Economy

Tax Burden, Tax Mix and Economic Growth in OECD Countries

Investment and Taxation in Germany - Evidence from Firm-Level Panel Data Discussion

Capital allocation in Indian business groups

An Empirical Investigation of the Lease-Debt Relation in the Restaurant and Retail Industry

Omitted Variables Bias in Regime-Switching Models with Slope-Constrained Estimators: Evidence from Monte Carlo Simulations

The Time Cost of Documents to Trade

Volume 30, Issue 1. Samih A Azar Haigazian University

INVESTMENT DECISIONS AND FINANCIAL STANDING OF PORTUGUESE FIRMS RECENT EVIDENCE*

Debt and Taxes: Evidence from a Bank based system

Impact of capital structure choice on investment decisions

Empirical Methods for Corporate Finance. Panel Data, Fixed Effects, and Standard Errors

The purpose of this paper is to examine the determinants of U.S. foreign

Stock price synchronicity and the role of analyst: Do analysts generate firm-specific vs. market-wide information?

Financial Constraints and the Risk-Return Relation. Abstract

Capital Structure and Financial Performance: Analysis of Selected Business Companies in Bombay Stock Exchange

Review of Recent Evaluations of R&D Tax Credits in the UK. Mike King (Seconded from NPL to BEIS)

Does the Equity Market affect Economic Growth?

저작권법에따른이용자의권리는위의내용에의하여영향을받지않습니다.

Does the interest rate for business loans respond asymmetrically to changes in the cash rate?

Asian Journal of Economic Modelling MEASUREMENT OF THE COST-OF-LIVING INDEX IN THE EASI MODEL: EVIDENCE FROM THE JAPANESE EXPENDITURE DATA

Capital structure and the financial crisis

Testing the Dynamic Trade-off Theory of Capital. Structure: An Empirical Analysis

THE DETERMINANTS OF CAPITAL STRUCTURE IN THE TEXTILE SECTOR OF PAKISTAN

The Speed of Adjustment to the Target Market Value Leverage is Slower Than You Think

INFLATION TARGETING AND INDIA

Capital Structure and Firm s Performance of Jordanian Manufacturing Sector

Threshold cointegration and nonlinear adjustment between stock prices and dividends

The Impact of Tax Policies on Economic Growth: Evidence from Asian Economies

On the nature of corporate capital structure persistence and convergence*

Chinese Firms Political Connection, Ownership, and Financing Constraints

Inequality and GDP per capita: The Role of Initial Income

Interest rate uncertainty, Investment and their relationship on different industries; Evidence from Jiangsu, China

The Yield Curve as a Determinant of Investment in Durable. Capital

Nature or Nurture? Data and Estimation Appendix

Tax Competition in European Diesel Excises

Modelling Inflation Uncertainty Using EGARCH: An Application to Turkey

Country Fixed Effects and Unit Roots: A Comment on Poverty and Civil War: Revisiting the Evidence

DETERMINANTS OF CORPORATE DEBT RATIOS: EVIDENCE FROM MANUFACTURING COMPANIES LISTED ON THE BUCHAREST STOCK EXCHANGE

The Determinants of Leverage of the Listed-Textile Companies in India

Financial Liberalization and Neighbor Coordination

Online Appendix to Grouped Coefficients to Reduce Bias in Heterogeneous Dynamic Panel Models with Small T

FE670 Algorithmic Trading Strategies. Stevens Institute of Technology

Public Expenditure on Capital Formation and Private Sector Productivity Growth: Evidence

Impact of the Stock Market Capitalization and the Banking Spread in Growth and Development in Latin American: A Panel Data Estimation with System GMM

Volume 35, Issue 1. Thai-Ha Le RMIT University (Vietnam Campus)

International Journal of Management (IJM), ISSN (Print), ISSN (Online), Volume 5, Issue 6, June (2014), pp.

An Empirical Examination of Traditional Equity Valuation Models: The case of the Athens Stock Exchange

Questioni di Economia e Finanza

Transcription:

Capital structure determinants and adjustment speed: An empirical analysis of Dutch SMEs Remco Mocking a, Joep Steegmans b, a CPB Netherlands Bureau for Economic Policy Analysis, P.O. Box 80510, 2508 GM Den Haag b Utrecht University School of Economics, P.O. Box 80125, 3508 TC Utrecht Abstract This paper presents empirical evidence of both the determinants and the adjustment speed of capital structure of small and medium-sized enterprises (SMEs) in the Netherlands. Using an administrative panel data set of the period 2000-2014, containing 153,923 firms, we estimate a partial adjustment model through system GMM. The results show that firm size and profitability reduce debt to assets ratios, while tangible assets, depreciation, and marginal taxes increase them. Growth of assets is either statistically or economically insignificant. The estimated adjustment speed parameter is 0.748, indicating that the adjustment process is particularly slow in the Netherlands. Keywords: Leverage, debt to assets, dynamic panel, SMEs 1. Introduction Explaining the capital structure of firms is a particularly difficult matter. In the corporate finance literature two theories dominate: trade-off theory (TOT) and pecking order theory (POT). TOT explains that tax advantages (tax shield of debt) provide incentives for debt financing, while costs of financial distress provide incentives for equity financing (Modigliani and Miller, 1963). In other words, firms face a trade-off in choosing between debt and equity financing. POT predicts that due to adverse selection firms prefer retained earnings to debt, while debt is preferred to equity (Myers, 1984). Frank and Goyal (2008), among others, have made it clear that the theories are not necessarily conflicting. They advocate that both considerations, the Corresponding author Email address: J.W.A.M.Steegmans@uu.nl (Joep Steegmans) July 11, 2017

focus on rational optimizing behavior (TOT) and the dominance of retained earnings over debt and equity (POT), have their merits. Recognizing that there is no single theory that can explain the capital structure of firms, explaining the financing choice has become primarily an empirical matter (Gaud et al., 2005). At least two questions are of special interest in this empirical literature. What firm characteristics drive the capital structure of firms? And, how fast do firms adjust their capital structure in response to policy changes or (firm) characteristics that influence the debt/equity mix? We will study both questions using a sample of small and medium-sized enterprises (SMEs) in the Netherlands. Our administrative data set from Statistics Netherlands (CBS) covers the period 2000-2014 and includes all Dutch firms liable to corporate income tax (CIT). Most importantly, the data set includes information from balance sheets and income and loss statements. Besides that, we obtained information on the industry in which the firm is active and we are able to construct the marginal tax rate by combining balance sheet data and historical tax rate changes. The final data set includes over 150,000 unique firms. This study contributes in at least two ways to the corporate finance literature, both related to the data. First, our data set is unique because the administrative nature ensures that we have representative information for a wide range of CIT-liable firms in the Netherlands, both in terms of size and industries. Previous empirical studies often rely on small data samples from large and/or publicly listed firms (e.g. Gaud et al., 2005; Ozkan, 2001). Second, our data allow us to estimate a partial adjustment model for Dutch SMEs. Although we are not the first to estimate a dynamic panel data model for SMEs (e.g. Aybar-Arias et al., 2012), the richness of our data allow us to check heterogeneity in the adjustment speed between industries and size classes. The structure of this paper is as follows. In section 2 we discuss the relevant literature and our contribution. Section 3 describes the data. Section 4 discusses the empirical model and the estimation strategy. Section 5 provides the estimation results. Section 6 offers robustness checks and section 7 summarizes and concludes. 2. Literature Multiple factors have been named in relation to the capital structure of firms. Nevertheless, the effects of these factors on firm leverage are not always obvious; predictions regularly differ between TOT and POT, and between different interpretations within each theory. Moreover, firm characteristics included in leverage regressions are often proxies for unobserved determinants. In this section we first discuss the most important firm characteristics that, according to theory, are related to the capital structure 2

of firms. Thereafter, we briefly discuss the recent empirical literature, with a special focus on dynamic panel data models and, related to that, estimates of adjustment speed. 2.1. Determinants Firm size If firm size is interpreted as a proxy for the volatility of earnings both TOT and POT predict a positive relationship between firm size and leverage; more diversified firms have less volatile earnings and lower default probabilities. Firms with less volatile earnings face lower borrowing costs leading to higher leverage. Size, however, might also proxy for other factors (Fama and French, 2002). For instance, large firms are better known and thus face lower adverse selection, making it easier to issue equity in comparison to smaller firms. POT is therefore often interpreted as predicting a negative effect of size on leverage, making the POT predictions ambiguous (Frank and Goyal, 2008). Tangible assets The relative amount of tangible (or fixed) assets is typically associated with higher levels of debt (e.g. Frank and Goyal, 2008, 2003). In TOT the argument is that fixed assets are a proxy for the amount of collateral, which reduces the cost of financial distress. Tangible assets are thus positively related to leverage. Collateral also mitigates information asymmetry problems, which reduces borrowing costs, implying that POT also predicts a positive relationship between tangible assets and leverage (e.g. Degryse et al., 2012). Most studies indeed find a positive relationship between tangible assets and leverage (Frank and Goyal, 2008). Growth opportunities TOT predicts that firms with high growth potential prefer less debt financing, because the costs of financial distress are higher for these firms. On the other hand, POT predicts a positive relationship between growth and leverage, since growing firms need more debt to finance their investments, holding profits constant (e.g. Frank and Goyal, 2009). Profitability According to TOT more profitable firms have higher debt to assets ratios. The explanation is twofold. First, more profitable firms have lower expected bankruptcy costs. Second, the interest tax shield is more valuable for firms with higher profits (Frank and Goyal, 2008). POT predicts exactly the opposite: firms prefer internal finance over external finance, which implies that more profitable firms have lower debt to assets ratios. This negative effect of profits is found in most empirical studies (Frank and Goyal, 2008). Depreciation Depreciation is mostly included in leverage regressions as a proxy for non-debt tax shields. The argument is that larger non-debt tax shields imply lower 3

taxable profits and, holding everything else constant, a lower payoff from interest tax shields (e.g. Fama and French, 2002). Following this line of reasoning depreciations should be negatively related to leverage according to TOT. Tax rate The main argument of TOT is that tax shields of debt provide incentives for debt financing. The obvious consequence is that higher (marginal) tax rates provide stronger incentives for debt financing. In other words, TOT predicts that higher tax rates lead to higher debt to assets ratios. In their meta-study Feld et al. (2013) conclude that higher tax rates are in general associated with higher leverage. However, the effects that are found depend to a large extent on how the tax rate is defined. The positive effect of tax rate on debt financing is most evident when marginal tax rates are used. 1 2.2. Empirical studies The empirical literature on the relationship between firm characteristics and leverage is very broad. Most empirical studies estimate equations with debt to assets ratio on the left-hand side and firm characteristics on the right-hand side. In recent years, more advanced econometric models have been used to study the relationship between firm characteristics and leverage. In particular, it has become more common to acknowledge the dynamic nature of capital structure. The dynamic process is estimated through panel data models with a lagged dependent variable. In what follows we briefly discuss some of these more advanced studies focusing on the adjustment speed of capital structure. Ozkan (2001) estimates a partial adjustment model based on a sample of 390 large UK companies. His preferred estimation method makes use of the Arellano- Bond estimator (difference GMM), where the explanatory variables are treated as endogenous. The coefficient of the lagged leverage variable is estimated to be 0.431 (0 indicates instant adjustment, while 1 indicates no adjustment), indicating that firms adjust their leverage relatively quickly to reach their target debt to assets ratios. The author contributes this finding to the trade-off between the costs of being off-target and the costs of leverage adjustment. Gaud et al. (2005) estimate a dynamic panel model using the Arellano-Bond (two-step) GMM estimator to explain the capital structure of 104 publicly listed Swiss companies. They treat all explanatory variables as endogenous since they are all based upon simultaneously determined accounting variables. They find an 1 For a discussion on the disadvantages of using the average corporate tax rate instead of the marginal corporate tax rate see Graham (2003). 4

adjustment coefficient in the range of 0.613-0.860 and conclude that adjustment in Switzerland is relatively slow compared to other countries. 2 Two possible explanations for the slow adjustment of Swiss companies are provided by the authors. First, stock prices were high during the sample period, which leads (by mechanics) to lower debt to assets ratios. Second, some of the firms benefited from the relatively loose credit conditions during the sample period to finance their business, leading to above target debt to assets ratios. Aybar-Arias et al. (2012) analyze the speed of adjustment to target debt ratios using a sample of 947 Spanish SMEs. Their preferred specification is a dynamic panel model estimated using the Blundell-Bond two-step system GMM estimator. As in Gaud et al. (2005) all explanatory variables are considered to be endogenous. The adjustment coefficient of 0.539 cannot be interpreted on its own since the model includes interaction terms between the lagged dependent variable and firm growth, firm size, distance to target leverage, and financial flexibility. The coefficients on the interaction terms show that larger firms, with a more flexible financial structure, and higher growth prospects adjust faster to their target debt ratio. The same holds for firms that are relatively close to their target leverage. 3. Data 3.1. Data set The microdata, covering the period 2000-2014, are obtained from Statistics Netherlands (CBS). The firm level data combine information from the Business Register (ABR, Algemeen Bedrijven Register) and Non-Financial Firms (NFO, Statistiek Financiën van niet-financiële ondernemingen). The latter data originate from the Ministry of Finance, which has a data base containing corporate tax declarations as provided to the tax authorities (Statistics Netherlands, 2015). 3 The matched microdata include annual balance sheets, profit and loss statements, and corporate taxes paid (or received). The data thus provide measures and/or proxies of the firm characteristics of Dutch SMEs. 2 Note that the different adjustments speeds found in different countries could very well be related to differences in the underlying samples used in the studies mentioned in this section. These are small samples and the studies do, for instance, not estimate adjustment speeds per industry, which would make it more easy to compare adjustment speeds in different countries. 3 Note that the sample of firms is limited to those firms paying CIT, meaning that sole proprietorships and partnerships (in Dutch: vennootschap onder firma) who pay personal income tax are not included in our data. 5

SMEs are selected based upon the definition that is used by the European Commission (2015). That is, enterprises should have an annual balance sheet total not exceeding 43 million euros and less than 250 employees (annual work units). 4 SMEs are divided into three categories: micro-enterprises, small enterprises, and mediumsized enterprises. Micro-enterprises have at most 10 employees and an annual balance sheet total of no more than 2 million euros. Small enterprises have at most 50 employees and an annual balance sheet total that does not exceed 10 million euros. The remaining enterprises are defined as medium-sized enterprises. We have an unbalanced panel data set as new enterprises start while others end. The data set does not contain gaps as firms with missing data have been eliminated. The remaining data set contains 745,640 observations of 153,923 unique firms. Extreme values are dealt with by winsorization (e.g. Frank and Goyal, 2008); that is, values smaller than the 1st percentile or larger than the 99th percentile are replaced with the value of the 1st and 99th percentile respectively. Apart from that firms with debt to assets ratios larger than one have been dropped as this implies the existence of negative shareholder equity, which is considered unlikely for healthy firms. 3.2. Variables and summary statistics The debt to assets ratio is defined as the sum of short-term debt (debt payable within 1 year), long-term debt (obligations lasting over 1 year), and trade payables divided by the annual balance sheet total. Trade payables are included in our definition as prior to 2005 only current liabilities are observed, which do include trade payables. Similarly, short-term debt to assets is defined as short-term debt and trade payables over the balance sheet total. Long-term debt to assets uses only long-term debt in the numerator. Short-term debt makes up over seventy percent of the total debt as illustrated by the average short-term and long-term debt to assets ratios, 0.254 and 0.108 respectively. Our set of explanatory variables includes proxies for the theoretical determinants of capital structure discussed in subsection 2.1. The size of the company is measured as the logarithm of the balance sheet total. Following the conventions in the literature tangible assets and depreciation are expressed as ratios, meaning that they too are divided by the annual balance sheet total. The return on assets (ROA), indicating firm profitability, is defined as the net profit after taxes divided by the balance 4 The definition allows for the use of annual turnover instead of annual balance sheet total too. The maximum of the annual turnover is set at 50 million euros. We will consistently use annual balance sheet total. 6

Table 1: Summary statistics of firm characteristics Mean Std.dev. Min Max Debt to assets ratio 0.362 0.274 0.001 1 Short-term debt to assets ratio 0.254 0.221 0 1 Long-term debt to assets ratio 0.108 0.177 0 1 Balance sheet total (in thousands of euros) 1,184.555 2,027.620 4 22,969 Log(balance sheet total) 6.198 1.340 1.386 10.042 Number of employees 6.703 13.952 0 219 Tangible assets* 0.175 0.219 0 0.951 Depreciation* 0.036 0.044 0 0.381 Return on assets 0.063 0.880-108.269 153 Growth of assets 0.063 0.507-0.973 12 Average tax rate 0.149 0.106 0 0.892 Marginal tax rate 0.177 0.092 0 0.345 Medium-sized firm (1 = yes) 0.028 0.164 0 1 Small firm (1 = yes) 0.206 0.405 0 1 Micro firm (1 = yes) 0.766 0.423 0 1 Duration (in years) 4.844 3.682 1 13 Observations 153,923 Notes: The means are based on firm averages in order to include firms only once. The sample thus consist of 153,923 unique firms. Following the convention both tangible assets and depreciation are scaled to total assets, as is the case with the debt to assets ratios. 7

sheet total (multiplied by 100 to get a percentage). Growth of assets measures the enterprise s expansion compared to the previous year, indicating particularly growth opportunities. It is important to note that total assets or balance sheet total are included in most of these measures, one way or another. The corporate taxes paid are used to determine the average and marginal tax rates. The average tax rate is defined as taxes paid divided by the profit before taxes; that is, we have not accounted for fiscal opportunities of carryback and carry forward of losses. Average tax rate is censored at zero as tax refunds do not truly imply negative tax rates. The profit before taxes is used as a measure of taxable income and determines the marginal tax rate. The corporate tax brackets between 2001 and 2014, determining the marginal tax rates, are given in table 2. Vrijburg (2013) thoroughly discusses carry back and carry forward of losses in the Netherlands and treats the assumptions under which he can take them into account in the marginal tax rate. We also obtained marginal tax rates by applying the carry back and carry forward rules. In the majority of cases the corrected marginal tax rate equals the naive marginal tax rate obtained by not taking carry back and carry forward into account. We include the naive marginal tax rate in our models, but the results are robust to including the corrected marginal tax rate. Table 2: Corporate tax brackets in the Netherlands (2001-2014) Year Taxable income Tax rate Taxable income Tax rate Taxable income Tax rate 2001 0-22,689 30.0 >22,689 35.0 2002 0-22,689 29.0 >22,689 34.5 2003 0-22,689 29.0 >22,689 34.5 2004 0-22,689 29.0 >22,689 34.5 2005 0-22,689 27.0 >22,689 31.5 2006 0-22,689 25.5 >22,689 29.6 2007 0-25,000 20.0 25,000-60,000 0.235 >60,000 25.5 2008 0-275,000 20.0 >275,000 25.5 2009 0-200,000 20.0 >200,000 25.5 2010 0-200,000 20.0 >200,000 25.5 2011 0-200,000 20.0 >200,000 25.0 2012 0-200,000 20.0 >200,000 25.0 2013 0-200,000 20.0 >200,000 25.0 2014 0-200,000 20.0 >200,000 25.0 Notes: Taxable income is measured in euros. Tax rate is given as a percentage. In 2008 new brackets were implemented during the year. We use the regulations that were in force at the end of the year as firms likely optimized their tax declarations based on the final regulations. 5 8

4. Empirical model 4.1. Dynamic model In order to study the capital structure of SMEs we model leverage, the ratio of debt and total assets, as a function of firm characteristics. In equilibrium, that is, when firms are at their targeted debt ratio, a static panel approach can be used. However, adjustment costs may prevent firms from immediately adjusting to its ideal debt to assets ratio. The existence of a target debt ratio would imply the use of a dynamic panel model. 6 To start with, we model target leverage as a function of firm characteristics where target ratios can differ between firms and over time. y i,t+1 = x itδ (1) where subscript i identifies the firm and subscript t identifies the year. The target debt to assets ratio is given by y, while the vector of firm characteristics determining the optimal capital structure is defined as x it. Note that the target and the firm characteristics are defined at time t + 1 and time t respectively. 7 The adjustment process is modeled with a partial adjustment model (e.g. Flannery and Rangan, 2006; De Jong et al., 2011). y i,t+1 y it = (1 λ)(y i,t+1 y it ) + α i + ɛ i,t+1 (2) Debt to assets ratio and its target are given by y and y respectively. The term α i is a time-invariant unobserved firm effect and ɛ i,t+1 is an error term. The speed of adjustment to the target is given by the term (1 λ). In a frictionless world λ equals zero, implying that adjustment is instant; higher values of λ imply slower adjustment. Substituting equation (1) into equation (2) and shifting from time t + 1 to time t leads to: y i,t = α i + λ(y i,t 1 ) + (x i,t 1)β + ɛ i,t (3) 5 Vrijburg (2013) does not include the late change in regulation. In his view the late policy change would have functioned as a lump-sum subsidy instead, thereby not changing firm behavior. The choice to include or exclude the late regulation changes does not affect our results. 6 Furthermore, the tax code also contains important dynamic aspects that cannot be properly represented in a single-period model (Frank and Goyal, 2008, p. 142). 7 We have defined the target at time t + 1 and the firm characteristics at time t, as is done by most scholars making use of a dynamic panel model (e.g. Flannery and Rangan, 2006). Others, for instance Gaud et al. (2005), define the target and firm characteristics in the same time period. It should be noted that the difference between both approaches is not eliminated by instrumenting the firm characteristics with the lagged values in the estimation process. 9

where β = (1 λ)δ. In other words, debt to assets ratio is a function of its lag, the lagged firm characteristics, and a time-invariant firm fixed effect. The vector x it in equation (3) includes a variety of firm characteristics that proxy for the theoretical determinants of firm capital structure (see section 2). In virtually all empirical studies on corporate capital structure the dependent variable and several independent variables are scaled to total assets; that is, profits, tangible assets, R&D expenditures, and depreciation (e.g. Flannery and Rangan, 2006; Hovakimian, 2006; Gaud et al., 2005; Degryse et al., 2012). However, scaling dependent and independent variables to total assets creates ratios that have a common denominator. These ratios are correlated even if the numerators are not; after all, an increase in total assets decreases all these ratios (e.g. Neyman, 1952; Firebaugh and Gibbs, 1985; Kronmal, 1993). It is for this reason that we will treat our explanatory variables as endogenous. 8 4.2. Estimation strategy Frank and Goyal (2008) identify three strategies that have been used for the estimation of dynamic panels. In early studies the long-term average is used as the target ratio. Later studies use a twostep procedure; that is, firm characteristics are used to estimate the target, after which the estimated target is substituted into the adjustment equation. More recently, scholars have started to substitute the target equation into the adjustment equation (see above). Through the use of dynamic panel estimators the model can be estimated in a single regression. We will apply the latter approach. The estimator that we use is determined by the particularities of our model and data set. Our model suggests the inclusion of fixed individual effects, a lagged dependent variable, and regressors that are endogenous. The inclusion of endogenous covariates is important as it allows us to deal with the previously mentioned scaling problems. 9 The data set implies the use of an estimator that is consistent for panels with few time periods and many individuals, a small T and large N. The small time dimension would lead to dynamic panel bias when Fixed Effects (FE) or Least Squares Dummy Variables (LSDV) are used for estimation. While the bias disappears when T approaches infinity, the Nickell bias, as it is generally called, can be severe when T is small (Nickell, 1981). 8 Ozkan (2001), Gaud et al. (2005), and Aybar-Arias et al. (2012) apply similar approaches. 9 For critical remarks on the use of lagged endogenous variables in corporate finance applications, see Roberts and Whited (2013) and Atanasov and Black (2017). Both studies argue that it is often hard to justify their use. 10

Generalized Method of Moments (GMM) provides two estimators that fit the particularities of our data set and model: difference GMM and system GMM, also known as the Arellano-Bond and Blundell-Bond estimator respectively (Arellano and Bond, 1991; Blundell and Bond, 1998). Both are designed for panels with small T and large N. They allow for a lagged dependent variable, endogenous regressors, and fixed individual effects. Difference GMM and system GMM are particularly useful when all available instruments are internal, that is, when they are based on lags of the instrumented variables (Roodman, 2009a). Difference GMM uses the set of available lags as instruments; system GMM extends the set of instruments with the lagged differences. System GMM is therefore more efficient. As external instruments are not available internal instruments are used to deal with the endogeneity due to scaling the dependent and (several) independent variables by total assets. Flannery and Hankins (2013) evaluate the performance of various dynamic panel estimators with simulated corporate finance data. In their simulations Kiviet s (1995) Least Squares Dummy Variable Correction (LSDVC) performs best overall, whereas the Blundell-Bond (system GMM) estimator appears to be the best choice in the presence of endogeneity. This is due to the fact that LSDVC, contrary to system GMM, assumes exogeneity of the regressors. The simulation results of Flannery and Hankins (2013) thus corroborate system GMM as our preferred estimator. 5. Results 5.1. Dynamic panel estimates The first two columns of table 3 present the estimated coefficients of equation (3) when, respectively, OLS and FE are used for estimation. While it is well-established that these estimators are biased for dynamic panels, they provide a likely upper and lower bound for the coefficient of the lagged dependent variable. Due to the positive correlation between the lagged dependent variable and the error the OLS results are likely to be biased upwards. The FE estimator, on the contrary, is likely to be biased downwards. In FE estimation demeaning introduces correlation between the demeaned lagged dependent variable and the demeaned error term when T is small. Nickell (1981) and Bond (2002) demonstrate that the negative bias dominates. It follows, therefore, that the true parameter of the lagged dependent variable should be larger than 0.462 yet smaller than 0.890. This indicates that the true parameter falls within the range of dynamic stability. Column 3 presents the results of the (two-step) system GMM estimation in which, apart from the lagged dependent variable, the regressors have been assumed exogenous. It should be noted, as we have discussed before, that this is a very strong 11

Table 3: Dynamic panel estimates (1) (2) (3) (4) OLS FE SysGMM (exo) SysGMM (endo) Lag debt to assets 0.890*** 0.462*** 0.770*** 0.748*** (0.001) (0.002) (0.004) (0.003) Lag log(size) 0.002*** -0.015*** -0.001*** -0.024*** (0.000) (0.001) (0.000) (0.001) Lag tangible assets 0.026*** 0.064*** 0.056*** 0.169*** (0.001) (0.002) (0.002) (0.004) Lag growth assets -0.001*** 0.002*** -0.004*** -0.001 (0.000) (0.000) (0.000) (0.000) Lag depreciation 0.066*** -0.001 0.181*** 0.042*** (0.004) (0.008) (0.006) (0.012) Lag ROA -0.015*** -0.024*** 0.033*** -0.058*** (0.001) (0.002) (0.002) (0.003) Lag marginal tax rate -0.030*** -0.030*** -0.004* 0.103*** (0.002) (0.002) (0.002) (0.003) Year fixed effects Yes Yes Yes Yes Hansen df 10 70 Hansen J stat 487.2 1406.8 Hansen p-value 0.000 0.000 AB test AR(2) z stat 7.90 8.82 AR(2) test p-value 0.000 0.000 Adj. R-sq 0.818 0.277 Observations 745,640 745,640 745,640 745,640 Notes: Dependent variable is debt to assets. Significance in columns 3 and 4 is based on Windmeijer corrected standard errors. * p<0.05, ** p<0.01, *** p<0.001. 12

assumption. The estimated coefficient of the lagged dependent variable is 0.770, indicating that adjustment towards the target is relatively slow. The estimates indicate a statistically significant negative effect of size, which however bears no economic significance. Growth of assets also seems to have a very small negative effect. The results indicate that tangible assets, depreciation, and return on assets have positive effects on debt to assets. Marginal tax rate has a negative sign, even though it is barely significant. The results of the two-step system GMM estimation with endogenous regressors, our preferred specification, are shown in column 4 of table 3. Firm size, tangible assets, growth of assets, and depreciation are treated as endogenous as they are defined in terms of balance sheet total. Marginal tax rate is assumed to be an exogenous regressor as balance sheet total is not directly related to it. 10 The coefficient of the lagged dependent variable is 0.748, which is well within the range we expect. The remaining regressors do show important differences compared to the exogenous estimation results. The negative effect of firm size remains but it becomes larger in magnitude, although the effect is still relatively small in economic terms. Tangible assets and depreciation continue to have positive effects, even though the magnitudes differ. In the endogenous specification the coefficient of growth of assets has become insignificant. The results indicate that profitability (return on assets) does not have a positive but a negative effect on debt to assets ratio. Furthermore, the effect of marginal tax rate has become positive in the endogenous specification, which in fact corresponds to theory. 11 A potential cause for concern regarding our system GMM estimates comes from the large set of (internal) instruments that is used (see Roodman, 2009a,b; Bowsher, 2002). Thus, even though the minimally arbitrary rule of thumb (Roodman, 2009a, p. 99), which specifies that the set of instruments should never be larger than the number of individual units, is met given the 153,923 unique firms in our data we have reduced the set of instruments by collapsing them (Roodman, 2009a,b), i.e. we have made them linear in T instead of quadratic. After all, the use of numerous instruments may bias coefficient estimates towards those from non-instrumenting estimators (Roodman, 2009b, p. 139). Furthermore, we have looked into reducing 10 It could be argued that tax rate is not strictly exogenous either. However, Graham (2003) demonstrates that endogeneity is most likely to bias results when the average tax rate is used. It is for that reason that we prefer the use of the marginal tax rate. 11 The estimates where the average tax rate is used instead of the marginal tax rate are shown in the appendix (see table A.8). The effect of average tax rate is significant and positive even though the magnitude is smaller. In addition, using the average instead of the marginal tax rate does not alter any of the conclusions. 13

the number of instruments by restricting the lag length (see Roodman, 2009a,b; Bowsher, 2002). Overall these latter estimates are similar to the estimates presented here. A weak Hansen test of instrument validity might be a symptom of instrument proliferation; that is, having too many instruments could lead to implausible high p-values for the Hansen J test for overidentifying restrictions (Roodman, 2009b). In other words, the rejection of the null hypothesis of the instruments being valid might be an indication that there being too many instruments is not our main concern. It is problematic, on the contrary, that the Hansen J statistic at the bottom of column 4 (Hansen J 1406.8, p-value 0.000) indicates that the null hypothesis of the overidentification restrictions being valid is rejected. 12 Autocorrelation across individuals is another reason to treat the estimates cautiously. While time dummies have been included in the specifications in order to reduce contemporaneous autocorrelation, the Arellano-Bond test statistics for second order autocorrelation, 7.90 in the exogenous specification and 8.82 in the endogenous specification, indicate that the instruments are not necessarily valid (Roodman, 2009a). 5.2. Adjustment speeds To investigate whether the adjustment speed differs between micro, small, and medium-sized firms we estimate separate regressions per firm type. Micro-enterprises are the smallest firms, while medium-sized enterprises are the largest of the SMEs (see section 3). Table 4 shows that micro-enterprises, making up about 75% of our sample, have the highest adjustment speed (lambda is 0.724). Nevertheless, mediumsized enterprises adjust quicker than small enterprises (lambda is 0.796 and 0.814 respectively). Thus even though micro firms have the highest adjustment speed, the observation that larger SMEs adjust slower is not supported by the estimated coefficients in the groups of small and medium-sized firms. Regarding the remaining variables only minor differences exist; that is, the coefficients of depreciation for the micro-enterprises and tangible assets and depreciation for the medium-sized enterprises are insignificant. Table 5 provides the estimates of adjustment speeds for the six industries with the largest number of firms in our data set: manufacturing, construction, wholesale, retail, information and communication (IC), and consultancy, research and other specialized business services (Consultancy). The latter two sectors seem to adjust the quickest to the target with lambdas of 0.660 and 0.685 respectively. Retail is the 12 The results and conclusions of the Sargan test are identical to those of the Hansen test. This holds for all test statistics throughout the paper. 14

Table 4: Estimates for micro, small, and medium-sized firms (1) (2) (3) Micro Small Medium Lag debt to assets 0.724*** 0.814*** 0.796*** (0.004) (0.007) (0.020) Lag log(size) -0.022*** -0.014*** 0.011 (0.001) (0.002) (0.008) Lag tangible assets 0.161*** 0.156*** 0.100*** (0.005) (0.009) (0.026) Lag growth assets -0.000-0.000-0.003 (0.000) (0.001) (0.002) Lag depreciation 0.022 0.111*** 0.040 (0.014) (0.024) (0.056) Lag ROA -0.043*** -0.074*** -0.069*** (0.003) (0.007) (0.019) Lag marginal tax rate 0.080*** 0.099*** 0.045** (0.003) (0.006) (0.014) Year fixed effects Yes Yes Yes Hansen df 70 70 70 Hansen J stat 1091.3 425.9 101.1 Hansen p-value 0.000 0.000 0.009 AB test AR(2) z stat 7.88 4.53-0.36 AR(2) test p-value 0.000 0.000 0.718 Observations 555,745 168,574 21,321 Notes: Dependent variable is debt to assets. Significance is based on Windmeijer corrected standard errors. * p<0.05, ** p<0.01, *** p<0.001. 15

sector with the slowest adjustment with a lambda of 0.849. All in all, the variation in adjustment speeds between sectors seems to be larger than between micro, small, and medium-sized enterprises. As before the remaining results remain mostly the same: size and return on assets have negative effects for all sectors, tangible assets and marginal tax rate always have positive effects. Growth of assets remains insignificant. Depreciation, however, shows some variation: the estimates show positive effects for construction and retail but are insignificant for the remaining sectors. Besides, second order autocorrelation does not seem to be a problem for the estimates of manufacturing and retail. Table 5: Estimates for different sectors (1) (2) (3) (4) (5) (6) Manufacturing Construction Wholesale Retail IC Consultancy Lag debt to assets 0.792*** 0.727*** 0.771*** 0.849*** 0.660*** 0.685*** (0.012) (0.011) (0.009) (0.013) (0.014) (0.007) Lag log(size) -0.017*** -0.028*** -0.033*** -0.016*** -0.023*** -0.029*** (0.004) (0.004) (0.003) (0.004) (0.004) (0.002) Lag tangible assets 0.156*** 0.179*** 0.185*** 0.092*** 0.182*** 0.142*** (0.013) (0.012) (0.012) (0.014) (0.021) (0.009) Lag growth assets -0.001-0.001-0.001-0.000-0.001 0.000 (0.001) (0.001) (0.001) (0.001) (0.001) (0.000) Lag depreciation 0.052 0.138*** 0.045 0.103* -0.008-0.009 (0.035) (0.038) (0.036) (0.050) (0.050) (0.024) Lag ROA -0.081*** -0.072*** -0.063*** -0.093*** -0.057*** -0.046*** (0.012) (0.010) (0.009) (0.014) (0.010) (0.004) Lag marginal tax rate 0.102*** 0.121*** 0.128*** 0.086*** 0.122*** 0.097*** (0.011) (0.010) (0.010) (0.011) (0.016) (0.006) Year fixed effects Yes Yes Yes Yes Yes Yes Hansen df 70 70 70 70 70 70 Hansen J stat 188.5 218.1 282.2 228.4 145.0 364.2 Hansen p-value 0.000 0.000 0.000 0.000 0.000 0.000 AB test AR(2) z stat 1.74 3.02 3.11 1.43 4.23 4.32 AR(2) test p-value 0.081 0.003 0.002 0.153 0.000 0.000 Observations 63,087 66,147 109,683 50,871 41,280 225,159 Notes: Dependent variable is debt to assets ratio. Significance is based on Windmeijer corrected standard errors. * p<0.05, ** p<0.01, *** p<0.001. 5.3. Short-term debt The short-term debt to assets ratio is expected to be easier adjustable than the total debt to assets ratio. After all, the shorter maturity of short-term debt implies that 16

adjustment towards the target should be quicker when long-term debt is not taken into account. Table 6 provides the (endogenous) two-step system GMM estimates where the short-term debt to assets ratio has been used instead of total debt to assets. The coefficient of the lagged dependent variable is 0.620, showing that the short debt to assets ratio indeed adjusts quicker towards the target. Apart from that the results are exactly the same. Size and profitability have negative effects. Tangible assets, depreciation, and tax rate have positive effects, while growth of assets remains insignificant. Table 6: Estimates with short-term debt to assets ratio Short-term debt Lag short-term debt to assets 0.620*** (0.004) Lag log(size) -0.029*** (0.001) Lag tangible assets 0.061*** (0.004) Lag growth assets -0.000 (0.000) Lag depreciation 0.136*** (0.011) Lag ROA -0.040*** (0.002) Lag marginal tax rate 0.064*** (0.003) Year fixed effects Yes Hansen df 70 Hansen J stat 1389.2 Hansen p-value 0.000 AB test AR(2) z stat 14.00 AR(2) test p-value 0.000 Observations 745,640 Notes: Dependent variable is short-term debt to assets. Significance is based on Windmeijer corrected standard errors. * p<0.05, ** p<0.01, *** p<0.001. 6. Robustness In order to investigate the robustness of our results we look into the observed duration of firms, i.e. the number of times that a firm is observed in our data set. In the 17

previous section we used all firms in our unbalanced panel, i.e. only firms with gaps between the observations have been excluded. Table 7 presents the results of the estimation of equation (3) where the required minimum number of observations per firm increases from two in column 1 to thirteen in column 12. 13 The latter column thus presents the results for firms observed in all years, making it a balanced panel. The coefficient of the lagged dependent variable seems to be exceptionally stable for all observed duration lengths: the coefficient ranges from 0.736 to 0.752. The results suggest that attrition bias or selection bias is not a problem in our study. Looking at the lambdas in more detail suggests that the estimated coefficient decreases up to a minimum observed duration of seven years and starts to increase afterwards, even though the differences are minimal. The results regarding the remaining explanatory variables are almost identical to those presented before too, even though some interesting patterns do occur: the effect of tangible assets decreases with the observed duration, while the negative effect of profitability increases with the minimum duration requirement. It is likely that these results are in fact age effects. Besides, size and depreciation exhibit an n-shape and u-shape pattern respectively. 7. Conclusions This paper presents empirical evidence of both the determinants and the adjustment speed of capital structure of small and medium-sized enterprises (SMEs) in the Netherlands. The unbalanced panel data set, covering the period 2000-2014, contains 745,640 observations of 153,923 firms. We use two-step system GMM to estimate a partial adjustment model, where we treat the explanatory variables as endogenous. The results show that firm size and profitability lead to lower debt to assets ratios. Tangible assets lead to higher debt to assets ratios, while growth of assets is either statistically or economically insignificant. Depreciation has a positive sign in most of the regressions. Nevertheless, it is insignificant in some of the estimations. Marginal tax rate is consistently found to have a positive effect. The results provide mixed evidence for the most dominant theories explaining the capital structure of firms, trade-off theory and pecking order theory. The negative effect of profitability is evidence in favor of POT and against TOT, while the lack of an effect of growth 13 Note that we need a minimum number of consecutive observations, because we first-difference and use lagged variables as instruments. A firm is included in the balanced panel if we have data available for the years 2002-2014. A firm is included in the baseline sample if we have data for at least three consecutive years, e.g. 2000-2002. 18

Table 7: Estimates for different duration lengths (unbalanced and balanced panels) (1) (2) (3) (4) (5) (6) (7) (8) (9) (10) (11) (12) Length 2 Length 3 Length 4 Length 5 Length 6 Length 7 Length 8 Length 9 Length 10 Length 11 Length 12 Balanced Lag debt to assets 0.746*** 0.745*** 0.744*** 0.739*** 0.738*** 0.736*** 0.737*** 0.744*** 0.746*** 0.745*** 0.749*** 0.752*** (0.004) (0.004) (0.004) (0.004) (0.004) (0.004) (0.004) (0.005) (0.005) (0.005) (0.006) (0.006) Lag log(size) -0.023*** -0.023*** -0.022*** -0.022*** -0.022*** -0.021*** -0.020*** -0.021*** -0.021*** -0.024*** -0.024*** -0.024*** (0.001) (0.001) (0.001) (0.001) (0.001) (0.002) (0.002) (0.002) (0.002) (0.002) (0.002) (0.002) Lag tangible assets 0.170*** 0.171*** 0.170*** 0.169*** 0.167*** 0.162*** 0.157*** 0.154*** 0.150*** 0.150*** 0.145*** 0.135*** (0.004) (0.004) (0.004) (0.004) (0.005) (0.005) (0.005) (0.005) (0.006) (0.006) (0.006) (0.007) Lag growth assets -0.001* -0.001*** -0.001*** -0.001*** -0.001* -0.000-0.000-0.000-0.000-0.000-0.000-0.001 (0.000) (0.000) (0.000) (0.000) (0.000) (0.000) (0.000) (0.000) (0.000) (0.000) (0.001) (0.001) Lag depreciation 0.045*** 0.050*** 0.058*** 0.059*** 0.045*** 0.039** 0.041** 0.039* 0.032 0.005 0.006-0.003 (0.012) (0.012) (0.012) (0.013) (0.013) (0.014) (0.015) (0.016) (0.017) (0.018) (0.020) (0.023) Lag ROA -0.057*** -0.060*** -0.064*** -0.069*** -0.070*** -0.069*** -0.073*** -0.076*** -0.079*** -0.085*** -0.083*** -0.087*** (0.003) (0.003) (0.003) (0.003) (0.003) (0.004) (0.004) (0.005) (0.005) (0.005) (0.006) (0.006) Lag marginal tax rate 0.101*** 0.103*** 0.102*** 0.103*** 0.097*** 0.091*** 0.090*** 0.091*** 0.091*** 0.095*** 0.091*** 0.090*** (0.003) (0.003) (0.004) (0.004) (0.004) (0.004) (0.005) (0.005) (0.005) (0.006) (0.006) (0.006) Year fixed effects Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Hansen df 70 70 70 70 70 70 70 70 70 70 70 70 Hansen J stat 1402.2 1413.4 1518.5 1506.8 1402.8 1330.4 1189.9 1106.2 971.7 835.8 710.7 612.2 Hansen p-value 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 AB test AR(2) z stat 8.85 8.92 9.10 9.32 9.35 9.16 9.48 8.63 8.22 7.14 5.90 4.38 AR(2) test p-value 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 Observations 715,937 665,441 611,156 550,428 489,948 428,742 343,566 301,694 267,584 231,414 193,200 153,660 Notes: Dependent variable is debt to assets ratio. Significance is based on Windmeijer corrected standard errors. * p<0.05, ** p<0.01, *** p<0.001. 19

does not provide evidence for either theory. The positive effect of taxes is evidence in favor of TOT. This paper thus corroborates that both theories have their merits without clearly favoring one theory over the other. The dynamic analysis provides evidence of a relatively slow adjustment process of Dutch SMEs: the estimated coefficient is about 0.748, while 0 indicates instant adjustment. This is similar to the very slow adjustment of publicly listed Swiss companies, which is in the range of 0.613-0.860 (Gaud et al., 2005). The coefficient that we find is, for instance, much larger than the one Ozkan (2001) finds for large UK companies (0.431). We find no clear pattern in adjustment speeds based on the size of SMEs: micro-enterprises have the highest adjustment speed (0.724), but small enterprises adjust slower (0.814) than medium-sized enterprises (0.796). The adjustment speeds of the six largest sectors range between 0.660-0.849. Consultancy, research and other specialized business services shows the highest adjustment speed, retail the lowest. Adjustment speeds thus seem to differ more between sectors than between size categories. Further evidence shows that, as expected, the short-term debt to assets ratio adjusts quicker (0.620) than the total debt to assets ratio. The slow adjustment speed of capital structure suggests limitations of policy makers to coerce short-term changes. It remains important to realize that our estimates should be interpreted with caution as overidentification is a problem in our estimates. Similarly, the existence of second order autocorrelation, which is present in most of our regressions, also indicates limitations to the choice of our empirical approach. Regarding the slow adjustment speed of capital structure the question remains why Dutch SMEs are relatively slow in their adjustments compared to firms in other European countries. Future research could provide policy makers with important insights into the reasons. 20

References Arellano, M., Bond, S., 1991. Some tests of specification for panel data: Monte carlo evidence and an application to employment equations. The review of economic studies 58 (2), 277 297. Atanasov, V. A., Black, B. S., 2017. The trouble with instruments: Re-examining shock-based IV designs. Working paper, SSRN, http://dx.doi.org/10.2139/ssrn. 2417689. Aybar-Arias, C., Casino-Martinez, A., Lopez-Gracia, J., 2012. On the adjustment speed of smes to their optimal capital structure. Small Business Economics 39 (4), 977 996. Blundell, R., Bond, S., 1998. Initial conditions and moment restrictions in dynamic panel data models. Journal of econometrics 87 (1), 115 143. Bond, S. R., 2002. Dynamic panel data models: a guide to micro data methods and practice. Portuguese economic journal 1 (2), 141 162. Bowsher, C. G., 2002. On testing overidentifying restrictions in dynamic panel data models. Economics letters 77 (2), 211 220. De Jong, A., Verbeek, M., Verwijmeren, P., 2011. Firms debt-equity decisions when the static tradeoff theory and the pecking order theory disagree. Journal of Banking & Finance 35 (5), 1303 1314. Degryse, H., de Goeij, P., Kappert, P., 2012. The impact of firm and industry characteristics on small firms capital structure. Small Business Economics 38 (4), 431 447. European Commission, 2015. User guide to the SME definition. Luxembourg: Publications Office of the European Union. Fama, E. F., French, K. R., 2002. Testing trade-off and pecking order predictions about dividends and debt. Review of financial studies 15 (1), 1 33. Feld, L. P., Heckemeyer, J. H., Overesch, M., 2013. Capital structure choice and company taxation: A meta-study. Journal of banking and finance 37, 2850 2866. Firebaugh, G., Gibbs, J. P., 1985. User s guide to ratio variables. American Sociological Review, 713 722. 21

Flannery, M. J., Hankins, K. W., 2013. Estimating dynamic panel models in corporate finance. Journal of Corporate Finance 19, 1 19. Flannery, M. J., Rangan, K. P., 2006. Partial adjustment toward target capital structures. Journal of financial economics 79 (3), 469 506. Frank, M. Z., Goyal, V., 2003. Testing the pecking order theory of capital structure. Journal of financial economics 67, 217 248. Frank, M. Z., Goyal, V., 2008. Trade-off and pecking order theories of debt. In: Eckbo, B. E. (Ed.), Handbook of Corporate Finance: Empirical Corporate Finance. Vol. 2. Elsevier/North-Holland, Ch. 12, pp. 135 202. Frank, M. Z., Goyal, V., 2009. Capital structure decisions: which factors are reliably important? Financial Management 38 (1), 1 37. Gaud, P., Jani, E., Hoesli, M., Bender, A., 2005. The capital structure of swiss companies: an empirical analysis using dynamic panel data. European Financial Management 11 (1), 51 69. Graham, J. R., 2003. Taxes and corporate finance: A review. Review of Financial studies 16 (4), 1075 1129. Hovakimian, A., 2006. Are observed capital structures determined by equity market timing? Journal of Financial and Quantitative analysis 41 (1), 221 243. Kiviet, J. F., 1995. On bias, inconsistency, and efficiency of various estimators in dynamic panel data models. Journal of econometrics 68 (1), 53 78. Kronmal, R. A., 1993. Spurious correlation and the fallacy of the ratio standard revisited. Journal of the Royal Statistical Society. Series A (Statistics in Society), 379 392. Modigliani, F., Miller, M. H., 1963. Corporate income taxes and the cost of capital: a correction. The American economic review 53 (3), 433 443. Myers, S. C., 1984. The capital structure puzzle. The journal of finance 39 (3), 574 592. Neyman, J., 1952. Lectures and conferences on mathematical statistics and probability, second edition Edition. Graduate School, US Department of Agriculture, Washington. 22

Nickell, S., 1981. Biases in dynamic models with fixed effects. Econometrica: Journal of the Econometric Society, 1417 1426. Ozkan, A., 2001. Determinants of capital structure and adjustment to long run target: evidence from uk company panel data. Journal of Business Finance and Accounting, 175 198. Roberts, M. R., Whited, T. M., 2013. Endogeneity in empirical corporate finance. Handbook of the Economics of Finance Volume 2, 493 572. Roodman, D., 2009a. How to do xtabond2: An introduction to difference and system gmm in stata. Stata Journal 9 (1), 86 136. Roodman, D., 2009b. A note on the theme of too many instruments. Oxford Bulletin of Economics and statistics 71 (1), 135 158. Statistics Netherlands, 2015. Documentatierapport statistiek financiën van nietfinanciële ondernemingen (NFO). Voorburg, The Netherlands: Centrum voor Beleidsstatistiek (8 April). Vrijburg, H., 2013. Testing the trade-off theory for dutch small and medium-sized enterprises. IIPF conference paper, Mimeo, Erasmus University Rotterdam. 23